植物逆境胁迫耐受性功能基因组研究进展

为了更加高效地利用基因工程技术提高植物对逆境胁迫的耐受性,需要在全基因组水平上对植物逆境胁迫耐受性的复杂机制进行整合性研究.植物逆境胁迫耐受性功能基因组的研究可概括为：利用胁迫特异性的表达序列标签(EST)及cDNA微阵列（或基因芯片）技术筛选与胁迫相关的候选基因,然后利用反向遗传学等技术对候选基因的功能进行研究,利用酵母双杂交、正向遗传学等技术对基因及基因产物间的相互关系进行研究.通过这些研究可以全面地了解植物对胁迫（渗透、干旱、极端温度）响应的复杂机制和相互作用以及相应的信号转导途径,从而为更加高效地利用基因工程技术提高植物对逆境胁迫的耐受性奠定基础.     

DREB转录因子与植物非生物胁迫抗性研究进展

干旱、高盐、低温等非生物逆境胁迫严重影响植物的生长发育和作物产量。转录因子在调节植物生长发育以及对外界环境胁迫的响应方面起着重要作用。DREB类转录因子即干旱应答元件结合蛋白是AP2/EREBP转录因子家族的一个亚家族,拥有保守的AP2结构域,能够与DRE/CRT顺式作用元件特异结合,在非生物逆境胁迫条件下调节一系列下游胁迫诱导逆境应答基因的表达,从而提高植物耐逆性。就DREB转录因子的结构特点、表达调控以及提高转基因植株胁迫耐受性的最新研究成果进行了评述。     

植物逆境相关启动子及功能

启动子是调控基因表达的重要顺式元件, 在植物基因表达调控过程中起着重要作用。目前植物抗逆基因工程中, 人们大多使用组成型表达启动子驱动目的基因的表达。组成型表达启动子虽然能提高转基因植株的抗逆性, 但是其持续过量地表达转化的外源基因会阻碍植物的生长且减少其产量。因此, 只在胁迫条件下才会驱动外源基因表达的诱导型启动子的研究显得尤其重要, 已成为目前研究的热点。文章综述了受非生物逆境和生物逆境胁迫诱导的植物基因启动子的种类和功能, 并展望了植物逆境诱导启动子的研究方向和前景。     

植物中DREBs类转录因子及其在非生物胁迫中的作用

低温、干旱、高盐等非生物胁迫能够严重影响植物的生长及作物的产量。最近发现了许多调控多种与逆境相关基因表达的转录因子, 其中DREBs类转录因子能够通过与含有DRE/CRT顺式作用元件的抗逆相关基因启动子区相互作用, 进而调控一系列抗逆基因的表达, 使植物品质得到综合改良从而提高植物对非生物胁迫耐受力。文章通过对DREBs的结构、表达调控、作用方式及机理进行总结, 并结合其在植物胁迫信号通路中的作用以及提高转基因植株胁迫耐受性的最新研究成果加以综述, 并对其在农业生产中的应用前景进行展望。     

拟南芥AtMPK3启动子应答逆境信号的表达模式和必需区域分析

蛋白激酶AtMPK3参与MAPK级联途径, 在植物逆境信号转导中起重要作用. 为深入研究AtMPK3基因在转录水平上应答各种环境胁迫的分子机制, 本研究从拟南芥基因组中分离了AtMPK3基因转录起始位点上游1016 bp的启动子序列, 对其进行了生物信息学分析. 对该启动子进行了系列缺失突变, 并将完整启动子和缺失启动子片段与GUS报告基因融合, 转基因导入到拟南芥中. 携带AtMPK3启动子及其各种缺失突变体的转基因植株在干旱、高盐、低温、机械损伤等胁迫条件的GUS组织化学染色和荧光定量分析表明, AtMPK3启动子应答干旱、高盐、低温、机械损伤逆境信号的必需元件位于启动子序列中转录起始位点上游−188 ~ −62区域内, 揭示了AtMPK3启动子在不同环境胁迫条件下的表达模式的差异. 本研究结果有助于阐述AtMPK3基因在转录水平上应答不同胁迫信号分子机制.     

水稻NHX1基因启动子和C末端的调控功能研究

为了解水稻Na+/H+逆向转运蛋白(OsNHX1)在植物应答非生物胁迫中的分子调控机制,采用RT-PCR方法克隆OsNHX1基因上游2 000bp的启动子序列,并通过基因枪轰击瞬时转化洋葱表皮细胞,检测不同非生物胁迫下启动子的活性和表达模式;同时,分别克隆全长和C末端缺失的OsNHX1基因,通过花序浸染法转化拟南芥,研究OsNHX1基因及其C末端的功能。结果显示:OsNHX1启动子受逆境胁迫诱导,在盐、干旱、脱落酸胁迫处理下GUS表达活性明显升高;过表达OsNHX1的转基因拟南芥中,种子萌发率、根长、丙二醛含量和相对含水量的测定结果均显示其胁迫耐受性得到改善,但过表达OsNHX1C末端缺失基因对转基因植株的胁迫耐受性无明显影响。研究表明,Na+/H+逆向转运蛋白有助于提高植物耐盐性,且其C末端区域对该转运蛋白活性的发挥具有关键作用。     

转铜/锌超氧化物歧化酶和抗坏血酸过氧化物酶基因马铃薯的耐氧化和耐盐性研究

高盐等逆境可以加剧植物体内活性氧的产生,进而引起植物细胞死亡。为开发抗逆境作物,以置于氧化诱导型启动子下定位于叶绿体的转铜/锌超氧化物歧化酶（Cu/ZnSOD）和抗坏血酸过氧化物酶基因(APX)马铃薯为材料,研究了其对MV和 NaCl所引起的氧化胁迫的耐受性。结果表明, MV胁迫下,转基因马铃薯叶片膜的相对电导率明显低于对照; NaCl胁迫下,其叶绿素含量高于对照。 在含NaCl 的培养基上,转基因幼苗生根率明显大于对照。另外,NaCl胁迫下转基因马铃薯叶片的SOD和APX酶活性显著高于对照,与其耐盐性的提高相一致。这些研究表明,转入Cu/ZnSOD和APX基因的马铃薯清除活性氧的能力增强,抗逆性得到提高。本实验采用氧化诱导型启动子调控下的SOD和APX两个基因协同作用,使外源基因只有在逆境胁迫时才特异性表达,增强转基因植株的抗逆效果,为培育抗逆经济作物开阔了思路。     

非生物逆境胁迫下ZmCIPK10基因表达分析

干旱、高盐、低温、高温等非生物逆境严重影响植物的生长发育,研究参与逆境胁迫应答基因具有重要的理论意义和应用价值。从玉米中克隆了一个CIPK蛋白激酶基因,暂时命名为ZmCIPK10。该基因全长2 730 bp,转录长度2 100 bp,编码438个氨基酸。顺式元件分析发现在基因启动子区域存在ABRE、HSE、TC-rich repeats等推测的逆境顺势元件。荧光实时定量PCR结果表明ZmCIPK10在干旱、低温、盐胁迫下表达量上调,在ABA、高温胁迫下表达量下调。研究结果初步证实ZmCIPK10基因响应非生物逆境胁迫,为ZmCIPK10参与植物逆境信号途径及其功能研究提供理论依据。     

玉米钼辅助因子硫酸化酶基因启动子的克隆与功能验证

为克服组成型启动子启动外源基因过量表达引起的诸多问题,同源克隆(Mo-molybdopterin cofactor sulfurase)基因（ABA3）的启动子(ABA3s)序列,并用PlantCARE软件分析其非生物逆境应答元件, 实时定量PCR检测ABA3基因在非生物逆境诱导下的差异表达后。然后,用该启动子构建启动GUS（β-glucuronidase）基因的表达载体, 基因枪法转化玉米愈伤组织。经组织化学染色法检测其表达后, 在高渗、高盐、低温胁迫处理及ABA诱导下检测GUS酶荧光值与荧光素酶(内参)发光值的比值(GUS/LUC), 以此评价ABA3s启动子在非生物逆境胁迫下的启动活性。结果表明, ABA3基因在模拟干旱、低温、高温、高盐胁迫及ABA、乙稀诱导下差异表达, 说明该基因的启动子(ABA3s)具有非生物逆境诱导活性。序列分析表明, ABA3s启动子全长777 bp, 含有ARE、HSE、MBS、TGA、Circadian等多种非生物逆境胁迫应答元件。用ABA3s启动GUS基因构建的表达载体转化的玉米愈伤组织, 响应干旱、低温、高温、高盐胁迫等多种非生物逆境胁迫, 及ABA和乙稀诱导, GUS检测呈阳性。在8%甘露醇高渗条件下, GUS/LUC比值比空白对照高6倍。上述结果表明, ABA3s启动子具有非生物逆境诱导特性, 经进一步验证其功能后, 可用于玉米抗逆转基因研究。     

高等植物胁迫诱导型启动子的研究进展

逆境胁迫严重影响植物生长发育,降低作物产量。目前在植物抗逆基因工程中,大多使用组成型启动子驱动目的基因表达,组成型启动子的表达虽然能提高转基因植株的抗逆性,但持续过量地表达转化的外源基因有时会阻碍植物的生长且降低其产量。因此,诱导型启动子的研究具有重要的应用价值。该文对近年来植物在逆境胁迫处理下,一些诱导型启动子的种类和功能,可能具有的顺式作用元件,反式作用因子及其研究方法进行了综述。     

拟南芥高迁移率族蛋白B（AtHMGB）族基因启动子的转录激活功能分析

为了解高迁移率族蛋白B族（high mobility group protein B,HMGB）基因调控植物响应低温、高盐和干旱等外源胁迫的表达调控方式, 本文克隆了拟南芥AtHMGB前5个家族成员的启动子区域（PAtHMGB1,PAtHMGB2,PAtHMGB3,PAtHMGB4和PAtHMGB5）.运用基因重组技术将其分别替换表达载体上35S启动子区域获得重组表达载体,利用农杆菌介导法侵染烟草获得稳定表达的转基因烟草. 运用实时定量PCR检测上述5种启动子的转基因烟草,观察在外源胁迫（低温、高盐和干旱）处理前后gusA基因的表达差异,同时检测转基因烟草种子在不同外源胁迫条件下的萌发状况. 检测结果证实,在低温胁迫下,PAtHMGB2,PAtHMGB3和PAtHMGB4正调控gusA基因的表达,而在干旱或盐胁迫下,gusA基因的表达被PAtHMGB2和PAtHMGB3负调控. 种子萌发结果表明,在干旱胁迫下,PAtHMGB2调控下的转基因烟草比野生型烟草萌发及生长迟缓|在低温胁迫下,PAtHMGB2调控的转基因烟草长势明显强于野生型. 本研究克隆了拟南芥AtHMGB家族前5个成员启动子,分析其生物学功能发现,PAtHMGB2在响应低温和干旱胁迫方面效果尤为显著.     

Activity of the Arabidopsis RD29A and RD29B promoter elements in soybean under water stress

The constitutive and drought-induced activities of the Arabidopsis thaliana RD29A and RD29B promoters were monitored in soybean (Glycine max (L.) Merr.] via fusions with the visual marker gene β-glucuronidase (GUS). Physiological responses of soybean plants were monitored over 9 days of water deprivation under greenhouse conditions. Data were used to select appropriate time points to monitor the activities of the respective promoter elements. Qualitative and quantitative assays for GUS expression were conducted in root and leaf tissues, from plants under well-watered and dry-down conditions. Both RD29A and RD29B promoters were significantly activated in soybean plants subjected to dry-down conditions. However, a low level of constitutive promoter activity was also observed in both root and leaves of plants under well-watered conditions. GUS expression was notably higher in roots than in leaves. These observations suggest that the respective drought-responsive regulatory elements present in the RD29X promoters may be useful in controlling targeted transgenes to mitigate abiotic stress in soybean, provided the transgene under control of these promoters does not invoke agronomic penalties with leaky expression when no abiotic stress is imposed.     

Engineered drought-induced biosynthesis of α-tocopherol alleviates stress-induced leaf damage in tobacco

Tocopherols are members of the vitamin E complex and essential antioxidant compounds synthesized in chloroplasts that protect photosynthetic membranes against oxidative damage triggered by most environmental stresses. Tocopherol deficiency has been shown to affect germination, retard growth and change responses to abiotic stress, suggesting that tocopherols may be involved in a number of diverse physiological processes in plants. Instead of seeking constitutive synthesis of tocopherols to improve stress tolerance, we followed an inducible approach of enhancing α-tocopherol accumulation under dehydration conditions in tobacco. Two uncharacterized stress inducible promoters isolated from Arabidopsis and the VTE2.1 gene from Solanum chilense were used in this work. VTE2.1 encodes the enzyme homogentisate phytyltransferase (HPT), which catalyzes the prenylation step in tocopherol biosynthesis. Transgenic tobacco plants expressing ScVTE2.1 under the control of stress-inducible promoters showed increased levels of α-tocopherol when exposed to drought conditions. The accumulation of α-tocopherol correlated with higher water content and increased photosynthetic performance and less oxidative stress damage as evidenced by reduced lipid peroxidation and delayed leaf senescence. Our results indicate that stress-induced expression of VTE2.1 can be used to increase the vitamin E content and to diminish detrimental effects of environmental stress in plants. The stress-inducible promoters introduced in this work may prove valuable to future biotechnological approaches in improving abiotic stress resistance in plants.     

Transgenic plants with improved dehydration-stress tolerance: Progress and future prospects

This review summarizes the recent progress made towards the development of transgenic plants with improved tolerance to water stress and salinity. Of the various strategies employed, emphasis has been given to the genes engineered for the biosynthesis of osmoprotectants and osmolytes. This review also briefly discusses the importance of the use of specific stress inducible promoters and the future prospects of transgenic plants with improved agronomic traits.     

Isolation and characterization of two sorbitol transporter gene promoters in micropropagated apple plants (Malus?×?domestica) regulated by drought stress

The role of polyol transporters in stress tolerance in plants have been elucidated by many studies. Sorbitol transporter genes MdSOT3, MdSOT4 and MdSOT5 in apple plants, which are important for sorbitol loading and unloading, are regulated by drought stress. To further confirm the role of sorbitol transporters in stress tolerance, the constructs harboring MdSOT3 and MdSOT5 genes were introduced into wild type Arabidopsis plants (Col-0) and the Arabidopsis transformed with MdSOT3 or MdSOT5 performed higher drought stress tolerance compared to WT. In order to further understand how sorbitol transporters are involved in drought tolerance in apple plants, upstream regions of sorbitol transporter genes were isolated from apple plant source leaves by Anchored PCR from genomic DNA obtained, and then were used to drive expression of the GUS reporter in tobacco plants. The results showed that the longest fragments of MdSOT3 and MdSOT5 promoters induced the highest GUS activity under drought stress conditions. Additionally, fragments of these promoters that contain cis-acting elements known to be involved in stress response also induced GUS activity under drought stress. Taken together, our data suggest that increased MdSOT3 and MdSOT5 activity, through cis-acting elements in the promoters of these genes, play important roles in imparting tolerance to drought in micropropagated apple plants.